所属学院：

  物理与光电工程学院

导师类别：

  硕士生导师

科研方向：

1. 微纳结构制备与表征技术

2. 纳米材料电子发射机制

3. 真空微纳电子器件物理

联系方式：

chenyic@gdut.edu.cn

硕博士招生学院：

  物理与光电工程学院

个人简述

(限300字)

陈毅聪是广东工业大学青年百人计划特聘副教授，硕士生导师。主要从事低维纳米材料微纳电子器件的研究。近年来，在Applied Physics Letters，IEEE Electron Device Letters，IEEE Transactions of Electron Devices等国际重要学术期刊上发表SCI学术论文30多篇，授权国家发明专利4项，主持国家自然科学基金面上项目和青年科学基金等项目。

学科领域

光电信息工程，电子科学与技术，材料物理与化学，电子信息技术

教育背景

20011/9 - 2016/12，中山大学，凝聚态物理，博士，导师：陈军

2007/9 - 2011/7，中山大学，微电子学，学士

工作经历

2025/01-至今，广东工业大学，物理与光电工程学院，特聘副教授

2023/07-2024/11，香港大学，博士后

2017/02-2023/02，中山大学，电子与信息工程学院，特聘副研究员

主要论文

[1] Yicong Chen; Zhibing Li^*; Jun Chen^*; Reducing the field emission energy spread of metal tip by tailoring the barrier shape. Journal of Applied Physics, 2026, 139: 084505.

[2] Guichen Song; Yicong Chen^*; Chunyi Wu; Zhipeng Zhang; Shaozhi Deng; Jun Chen^*; Boosting the Emission Efficiency of Graphene/hBN Tunneling Cathode by Constructing an Asymmetric Tunneling Barrier. IEEE Electron Device Letters, 2026, 47: 164-167.

[3] Guichen Song; Yicong Chen; Zhibing Li; Shaozhi Deng; Jun Chen^*; Electron emission efficiency of graphene/h-BN/2D-semiconductor heterostructure: theoretical analysis and experimental verification. Physica Scripta, 2025, 100: 035007

[4] Xinran Li; Yicong Chen; Guichen Song; Runzei Zhan; Haoshen Cao; Qi Liu; Zhuoran Ou; Zhipeng Zhang; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Enhancing field emission properties of ZnO nanowires via atomic layer deposition coated ultrathin TiN films. Vaccum, 2025, 241: 114689

[5] Yicong Chen; Chengyun Wang; Guichen Song; Shaozhi Deng; Jun Chen^*; Modeling the Temporal Response of Gated ZnO Nanowire Field Emitter by Considering the Charging and Self-Heating Effect for Improving the Response Speed. Electronics, 2024, 13: 796.

[6] Zhuoran Ou; Chengyun Wang; Guichen Song; Yicong Chen; Xinran Li; Guofu Zhang; Shaozhi Deng; Jun Chen^*; A Universal Model for Analytical Investigation of Electrical Characteristics of Planar-Gate Nanowire Field Emitters. IEEE Transactions on Electron Devices, 2024, 71: 7810-7817.

[7] Yicong Chen; Dong-Keun Ki^*; Zhibing Li; Jun Chen^*; Concept for a fractional energy barrier tunneling junction. Applied Physics Letters, 2023, 123: 243503.

[8] Yicong Chen; Jun Chen; Zhibing Li^*; Cold cathodes with two-dimensional van der Waals materials. Nanomaterials, 2023, 13: 2437.

[9] Guichen Song; Yicong Chen^*; Shaozhi Deng; Jun Chen^*; Improving the collection efficiency in the hot carrier tunneling device by optimizing the thickness of tunneling barrier for balancing the acceleration and scattering processes. Applied Physics Letters, 2023, 122: 063501.

[10] Song Kang; Yicong Chen; Chengyun Wang; Guofu Zhang; Shaozhi Deng; Jun Chen^*; Transparent Flat Panel X-Ray Source Using ITO Transmission Anode and ZnO Nanowire Cold Cathode. IEEE Transactions on Electron Devices, 2023, 70: 3302-3307.

[11] Zekun Guo, Haojian Lin, Hu Zhang, Yan Tian, Yicong Chen, Jun Chen, Shaozhi Deng, and Fei Liu^*, Low-Pressure CVD Synthesis of Tetragonal Borophene Single-Crystalline Sheets with High Ambient Stability, Crystal Growth & Design, 2023, 23: 4506–4513.

[12] Yicong Chen; Xuqi Wang; Libin Wang; Chengyun Wang; Guofu Zhang; Juncong She; Shaozhi Deng; Jun Chen^*; Quantitative analysis on the field strength in the addressable gated ZnO nanowire field emitter arrays: model and experiment. IEEE Transactions on Electron Devices, 2022, 69: 5206-5210.

[13] Deyi Huang; Yicong Chen^*; Chengyun Wang; Juncong She; Shaozhi Deng; Jun Chen; Improving the response speed of an active-current controlled field emitter arrays by modifying the controlled current. IEEE Transactions on Electron Devices, 2022, 69: 5895-5899.

[14] Yicong Chen; Yu Zhang; Juncong She; Shaozhi Deng; Jun Chen^*; Theoretical analysis of self-heating and cooling processes in the pulsed field emission from ZnO nanowire for achieving high emission current. IEEE Transactions on Electron Devices, 2022, 69: 7033-7038.

[15] Yangyang Zhao, Yicong Chen, Guofu Zhang, Deyi Huang, Runze Zhan, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Pulsed voltage driving enhanced electron emission in ZnO nanowire cold cathode flat-panel X-ray source, Vacuum, 2022, 199: 110970.

[16] Min Sun, Guowu Tang, Hanfu Wang, Ting Zhang, Pengyu Zhang, Bin Han, Ming Yang, Hang Zhang, Yicong Chen, Jun Chen, Qingfeng Zhu, Jiangyu Li, Dongdan Chen, Jiulin Gan, Qi Qian, Zhongmin Yang^*, Enhanced Thermoelectric Properties of Bi₂Te₃-Based Micro–Nano Fibers via Thermal Drawing and Interfacial Engineering, Advanced Materials, 2022, 34: 2202942.

[17] Yicong Chen; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Recent Progress on ZnO Nanowires Cold Cathode and Its Applications. Nanomaterials, 2021, 11: 2150.

[18] Yicong Chen; Zhibing Li; Shisong Luo; Shaozhi Deng; Jun Chen^*; Concept for Realizing High Output Power Density Thermionic Energy Convertor by Field-Assisted Thermionic Emission Using a Direct-Tunneling Metal–Insulator–Graphene Cathode. IEEE Transactions on Electron Devices, 2021, 68: 4144-4149.

[19] Yangyang Zhao, Yicong Chen, Guofu Zhang, Runze Zhan, Juncong She, Shaozhi Deng, Jun Chen^*, High Current Field Emission from Large-Area Indium Doped ZnO Nanowire Field Emitter Arrays for Flat-Panel X-ray Source Application. Nanomaterials, 2021, 11: 240.

[20] Shisong Luo, Yicong Chen, Zhibing Li^*, Jun Chen^*, Theoretical analysis of efficiency for vacuum photoelectric energy converters with plasmon-enhanced electron emitter. Journal of Applied Physics, 2021, 130: 023104.

[21] Chengyun Wang, Guofu Zhang, Yuan Xu, Yicong Chen, Shaozhi Deng, Jun Chen^*, Fully Vacuum-Sealed Diode-Structure Addressable ZnO Nanowire Cold Cathode Flat-Panel X-ray Source: Fabrication and Imaging Application, Nanomaterials, 2021, 11: 3115.

[22] Yicong Chen; Zhibing Li^*; Jun Chen^*; Abnormal Electron Emission in a Vertical Graphene/Hexagonal Boron Nitride van der Waals Heterostructure Driven by a Hot Hole Induced Auger Process. ACS Applied Materials & Interfaces, 2020, 12: 57505-57513.

[23] Yicong Chen; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Energy-tunable Photon-enhanced Thermal Tunneling Electrons for Intrinsic Adaptive Full Spectrum Solar Energy Conversion. Applied Physics Letters, 2020, 116: 063902.

[24] Yicong Chen; Shisong Luo; Xiuqing Cao; Yufeng Li; Juncong She; Shaozhi Deng; Jun Chen^*; Stable Heating Above 900 K in the Field Emission of ZnO Nanowires: Mechanism for Achieving High Current in Large Scale Field Emitter Arrays. Advanced Electronic Materials, 2020, 6: 2000624.

[25] Yicong Chen; Liwei Liu; Keshuang Zheng; Juncong She; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Highly Stable Field Emission from a Tungsten Diselenide Monolayer on Zinc Oxide Nanowire by Geometrically Modulating Hot Electrons. Advanced Electronic Materials, 2019, 5: 1900128.

[26] Yicong Chen; Zhipeng Zhang; Zhibing Li; Juncong She; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Investigation of the Temperature Dependent Field Emission from Individual ZnO Nanowires for Evidence of Field-induced Hot Electrons Emission. J. Phys. Condens. Mat. 2018, 30: 315002.

[27] Yicong Chen; Xiaomeng Song; Zhibing Li; Juncong She; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Penetration Length-dependent Hot Electrons in the Field Emission from ZnO Nanowires. Applied Surface Science, 2018, 427: 573-580.

[28] Yicong Chen; Xiaomeng Song; Zhibing Li; Shaozhi Deng; Juncong She; Ningsheng Xu; Jun Chen^*; In-situ Determination of the Flat Band Carrier Concentration and Surface Charge Density of Individual Semiconductor Nanowires by a Combination of Electrical and Field Emission Measurements. Journal of Applied Physics, 2017, 121: 174306.

[29] Yicong Chen; Chengchun Zhao; Feng Huang; Runze Zhan; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; In situ Characterization of the Local Work Function along Individual Free Standing Nanowire by Electrostatic Deflection. Scientific Reports, 2016, 6: 21270.

[30] Yicong Chen; Shaozhi Deng; Ningsheng Xu; Jun Chen^*; Origin of the Ring-shaped Emission Pattern Observed from the Field Emission of ZnO Nanowire: Role of Adsorbates and Electron Initial Velocity. Material Research Express, 2014, 1: 045050.

[31] Long Zhao, Yicong Chen, Zhipeng Zhang, Xiuqing Cao, Guofu Zhang, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Coplanar-gate ZnO nanowire feld emitter arrays with enhanced gate-control performance using a ring-shaped cathode. Scientific Reports, 2018, 8: 12294.

[32] Ying Wang, Yicong Chen, Xiaomeng Song, Zhipeng Zhang, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Electrical properties of fluorine-doped ZnO nanowires formed by biased plasma treatment. Physica E: Low-dimensional Systems and Nanostructures, 2018, 99: 254-260.

[33] Zufang Lin, Runze Zhan, Yicong Chen, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Defective WO_3−x nanowire: possible long lifetime semiconductor nanowire point electron source, Nanoscale, 2019, 11: 3370-3377.

[34] Zhipeng Zhang, Xiaomeng Song, Yicong Chen, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Controllable preparation of 1-D and dendritic ZnO nanowires and their large area field-emission properties, Journal of Alloys and Compounds, 2017, 690: 304-314.

[35] C X Zhao, Y F Li, Y C Chen, J Q Wu, B Wang, F T Yi, S Z Deng, N S Xu, J Chen^*, Microstructure change of ZnO nanowire induced by energetic x-ray radiation and its effect on the field emission properties, Nanotechnology, 2013, 24: 275703.

[36] Zhipeng Zhang, Daokun Chen, Wenqing Chen, Yicong Chen, Xiaomeng Song, Runze Zhan, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Thermo-enhanced field emission from ZnO nanowires: Role of defects and application in a diode flat panel X-ray source, Applied Surface Science, 2017, 399: 337-345.

[37] Zufang Lin, Peng Zhao, Peng Ye, Yicong Chen, Haibo Gan, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Maximum field emission current density of CuO nanowires: theoretical study using a defect-related semiconductor field emission model and in situ measurements, Scientific Reports, 2018, 8: 2131.

[38] Zufang Lin, Wenqing Chen, Runze Zhan, Yicong Chen, Zhipeng Zhang, Xiaomeng Song, Juncong She, Shaozhi Deng, Ningsheng Xu, Jun Chen^*, Thermal-enhanced field emission from CuO nanowires due to defect-induced localized states, AIP Advances, 2015, 5: 107229.

知识产权

[1] 陈军、陈毅聪、佘峻聪、邓少芝、许宁生，一种高稳定电子发射的复合纳米冷阴极结构及制备方法，中国 发明专利，专利号：ZL 201811595040.X，申请日期：2018年12月25日，授权日期：2020年07月03日，中山大学

[2] 陈军、陈毅聪、邓少芝、许宁生，一种中低温真空热电转换器件及其制备方法，中国发明专利，专利号： ZL 201910381775.0，申请日期：2019年05月08日，授权日期：2020年11月27日，中山大学

[3] 陈军、陈毅聪、邓少芝、许宁生，一种可调的真空光热电转换太阳电池及其制备方法，中国发明专利，专利号：ZL 201910779150.X，申请日期：2019年08月22日，授权日期：2021年09月21日，中山大学

[4] 陈毅聪、陈军、邓少芝、许宁生，一种环形可寻址冷阴极X射线源器件及其制备方法和应用，中国发明专利，专利号：ZL 202111228022.X，申请日期：2021年10月21日，授权日期：2024年04月26日，中山大学

科研项目

1. 国家自然科学基金面上项目，项目批准号：62571143，基于石墨烯边缘的横向分形势垒隧穿阴极电子源研究，2026.01-2029.12，50万，主持。

2. 国家自然科学基金青年项目，项目批准号：61701551，半导体纳米线的电子输运空间分布对其场发射特性的作用机理研究，2018.01-2020.12，25万，已结题，主持。

3. 广东省自然科学基金，项目批准号：2022A1515012008，二维材料垂直异质结MIM阴极在光和热激励下的电子发射机理研究，2022.01-2024.12，10万，已结题，主持。

4. 广州市科技计划基础项目一般项目，项目批准号：202201011519，氧化锌纳米线在脉冲电场下的电子发射机理及热管理研究，2022.04-2024.03，5万，已结题，主持。

5. 高校基本科研业务费青年教师培育项目，项目批准号：18lgpy19，二维原子晶体薄膜的电子隧穿机理研究，2018.01-2020.12，15万，已结题，主持。

6. 广东工业大学青年百人科研启动经费，2025.01-2029.12，20万，主持。

7. 科技部国家重点研发计划，项目批准号：2022YFA1204200，平板X射线源与探测器及视频适形CT成像关键技术研究，2023.05-2028.04，2400万，参与。

8. 科技部国家重点研发计划，项目批准号：2016YFA0202001，新型纳米冷阴极平板X射线源和高灵敏度探测器件及其CT图像重建方法研究，2016.07-2021.06，2500万，已结题，参与。

9. 科技部国家重点研发计划，项目批准号：2021YFA1200601，并行电子束关键技术与高通量检测系统，2021.12-2026.11，800万，参与。

10. 广东省重点领域研发计划项目，项目批准号：2020B0101020002，基于碳纳米管的脉冲式微米级焦斑冷阴极X射线源研制，2020.06-2023.06，230万，已结题，参与。

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